Experimental Therapy Restores Nerve Insulation Damaged by Disease

Lab Tests Show Treatment Might Help People with Autoimmune Diseases

Monday, February 12, 2018

Restoring Nerve Insulation

This image from a paper in Nature Medicine shows how inhibiting an enzyme called HDAC3 in mice increases the expansion of Schwann cells (green). Schwann cells form a protective insulating layer called the myelin sheath around the nerves. Blocking HDAC3 increases the production of myelin proteins, shown in red. Scientists from Cincinnati Children’s tested an experimental molecular therapy in the mice that restored nerve insulation and improved limb function following nerve injury.

When the body attacks its own healthy tissues in an autoimmune disease, peripheral nerve damage handicaps people and causes persistent neuropathic pain when insulation on healing nerves doesn’t fully regenerate.

Unfortunately, there are no effective ways to treat the condition. Now scientists at Cincinnati Children’s Hospital Medical Center describe in Nature Medicine an experimental molecular therapy that restores insulation on peripheral nerves in mice, improves limb function, and results in less observable discomfort.

To identify possible therapies, the international team of investigators performed small-molecule epigenetic screening for compounds that inhibit enzymes involved in epigenetic changes on chromosomes. These changes alter how gene activity in cells is regulated. The authors identified small molecular inhibitors already used to treat certain cancers and tested them in experimental treatments on mice with injured sciatic nerves.

Restoring Signal Relays

The peripheral nervous system relays signals from the brain and spinal cord (the central nervous system) to limbs and organs. HDAC3 is an enzyme found in humans and mice. Its usual job in peripheral nerve formation is to act as a molecular brake on the production of the myelin coating by Schwann cells.

After peripheral nerve injury, HDAC3 initiates epigenetic changes to chromosomes and gene regulation that excessively restrict myelin regeneration. This results in nerve insulation that is too thin or not totally formed, blocking or slowing signals between the spinal cord, extremities and organs.

Timing is Crucial

Researchers carefully timed their targeted treatments when inhibiting HDAC3, treating the mouse models of nerve injury only during a critical phase of nerve regeneration. This resulted in the right amount of re-myelination to restore normal function in the animals.

Getting the timing right on transient treatment is critical, Lu says. Researchers show that blocking HDAC3 for too long allows myelin to overgrow and cause excessively thick insulation. This also can lead to functional problems in extremities, according to study data.

From Science to Medicine

Translating data in the current study to clinical application in human patients will require extensive additional research, Lu says. Now that the prospective therapy has been successfully tested in mice, researchers are exploring additional research in animal models that more closely mimic the repair of injured peripheral nerves in people. This includes looking specifically at some demyelinating diseases that affect the central nervous system, such as multiple sclerosis.

Lu said this work will allow scientists to replicate and verify their findings in mice and other laboratory models. They also will be able to test possible dosing levels. If results are positive, Lu said researchers could pursue possible Phase I clinical trials in patients having deficient myelin in their peripheral and central nervous systems.

Other collaborating institutions on the study include co-authors from the Children’s Hospital of Fudan University (Shanghai, China), the Lerner Research Institute at the Cleveland Clinic, the Department Biological Chemistry & Pharmacology at the Ohio State University (Columbus, OH), National Institute of Child Health and Human Development (NIH), the Washington University School of Medicine (St. Louis), and the Department of Neurogenetics, Max Planck Institute of Experimental Medicine (Göttingen, Germany).

Funding support came in part from grants by the National Institutes of Health (R37NS096359, R01NS075243, R35NS097303, R01AR064551-01A1) and the National Multiple Sclerosis Society (NMSS-RG1507).